High sensitivity and fast response are the figures of merit for benchmarking commercial sensors.Due to the advantages of intrinsic signal amplification,bionic ability,and mechanical flexibility,electrochemical transis...High sensitivity and fast response are the figures of merit for benchmarking commercial sensors.Due to the advantages of intrinsic signal amplification,bionic ability,and mechanical flexibility,electrochemical transistors(ECTs)have recently gained increasing popularity in constructing various sensors.In the current work,we have proposed a pulse-driven synaptic ECT for supersensitive and ultrafast biosensors.By pulsing the presynaptic input(drain bias,VD)and setting the modulation potential(gate bias)near transconductance intersection(VG,i),the synaptic ECT-based pH sensor can achieve a record high sensitivity up to 124 mV pH^(-1)(almost twice the Nernstian limit,59.2 mV pH^(-1))and an ultrafast response time as low as 8.75 ms(7169 times faster than the potentiostatic sensors,62.73 s).The proposed synaptic sensing strategy can effectively eliminate the transconductance fluctuation issue during the calibration process of the pH sensor and significantly reduce power consumption.Besides,the most sensitive working point at VG,i has been elaborately figured out through a series of detailed mathematical derivations,which is of great significance to provide higher sensitivity with quasi-nonfluctuating amplification capability.The proposed electrochemical synaptic transistor paired with an optimized operating gate offers a new paradigm for standardizing and commercializing high-performance biosensors.展开更多
Formaldehyde(FA),as the simplest endogenous carbonyl molecule,participates in many biosynthesis and metabolism in living organisms,such as nucleotides and adenosine triphosphate(ATP).FA concentrations are sub-millimol...Formaldehyde(FA),as the simplest endogenous carbonyl molecule,participates in many biosynthesis and metabolism in living organisms,such as nucleotides and adenosine triphosphate(ATP).FA concentrations are sub-millimolar in the normal healthy body,but can rise significantly in a number of disease pathologies.As a result,detecting endogenous FA is critical for illness diagnosis and rehabilitation therapy monitoring.Recent studies have focused on the FA-responsive turn-on fluorescence probe,which has huge promise in the detection and visualization of FA in living cells and organisms,as well as exceptional use in disease diagnosis and therapeutic monitoring.This review summarizes the fluorescence luminescence mechanism and design concepts of FA fluorescent probes,as well as their recent applications in bioimaging and illness diagnostics.Additionally,this article indicates the present dilemma of FA-responsive fluorescent probe,including selectivity,specificity,and detection mode,which may provide references for the development of FA-responsive fluorescent probes.展开更多
Over the past decade, biopolymers have gained great interests especially in biomedicine due to their physical properties and/or chemical structures changes in response to external stimuli in a certain time fiarne or a...Over the past decade, biopolymers have gained great interests especially in biomedicine due to their physical properties and/or chemical structures changes in response to external stimuli in a certain time fiarne or at a specific location. Among them, poly(β-amino ester)s, methacrylate-based block copolymers and polypeptide with tertiary amine groups have been extensively studied and exhibit pH sensitive properties due to the protonation of tertiary amine groups. The pH values in normal organs, tissues, and subcellular compartments are always different from those in pathological tissues. These interesting properties allow their applications in a variety of fields ranging from diagnosis and therapeutics of diseases. Here, we review the recent progress of poly(β-amino ester)s, methacrylate-based block copolymers and polypeptide with tertiary amine groups and their applications in drug delivery and bioimaging.展开更多
The interfacing study of biopolymer and supramolecular chemistry enables a better understanding of fundamental biochemical processes and the creating of new high-performance biomaterials. In this review, we introduced...The interfacing study of biopolymer and supramolecular chemistry enables a better understanding of fundamental biochemical processes and the creating of new high-performance biomaterials. In this review, we introduced an "in vivo self-assembly" strategy which means in situ construction of functional self-assembled superstructures in specific physiological or pathological conditions in cell, tissue or animal levels that exhibit diverse biomedical effects. By using this strategy, unexpected phenomena and insights, e.g, assembly/aggregation induced retention (AIR) effect have been demonstrated where the self-assembled nanostructures showed extraordinary enhanced accumulation and retention of therapeutics in targeted sites.展开更多
The self-assembled nanomaterials based on peptides,which have not only good biocompatibility and low toxicity but also high stability and performance,are increasingly becoming an important way for cancer treatment.In ...The self-assembled nanomaterials based on peptides,which have not only good biocompatibility and low toxicity but also high stability and performance,are increasingly becoming an important way for cancer treatment.In this review,we highlight the progress of in vivo self-assembled polymer-peptide conjugates(PPCs)and their application,showing the recent advances in the development of“in vivo self-assembly”strategy for cancer treatment.Given the diverse microenvironments of tumor cells,different responsive assembly strategies(enzyme,pH,redox,temperature,etc.)have been developed to precisely control the assembly at different biological levels,realizing enhanced drug delivery and improved anticancer efficacy.展开更多
Luminogens with aggregation-induced emission(AIEgens)have a wide range of biomedical applications in bioimaging,photodynamic anticancer,antibacterial therapy,and other fields,owing to their unique photophysical proper...Luminogens with aggregation-induced emission(AIEgens)have a wide range of biomedical applications in bioimaging,photodynamic anticancer,antibacterial therapy,and other fields,owing to their unique photophysical properties.The precise structural design and modification of AIE molecules have aroused great interest in the past years.As peptides-AIE hybrid materials,peptide-based AIEgens generally have better solubility,biocompatibility,and lower systemic toxicity.The functional diversity,modularity,and portability of peptides provide more possibilities for the intelligent structure and functional design of AIEgens.This review summarizes the recent research progress of peptide-based AIEgens nanomaterials,from molecular design,stimuli responsiveness to biomedical application,focusing on the advantages of peptides and AIE molecules as conjugates.Finally,a summary of the challenges and opportunities of peptide-based AIEgens nanomaterials for future clinical biomedical applications is presented.展开更多
基金National Natural Science Foundation of China,Grant/Award Numbers:61703298,51975400,52073031,52175542Natural Science Foundation of Shanxi Province,Grant/Award Number:20210302123136+3 种基金China Postdoctoral Science Foundation,Grant/Award Number:2020M673646National Key Research and Development Program of China,Grant/Award Numbers:2021YFB3200304,2016YFA0202703Beijing Nova Program,Grant/Award Number:Z211100002121148Patent Transformation Special Program of Shanxi Province,Grant/Award Number:202304012。
文摘High sensitivity and fast response are the figures of merit for benchmarking commercial sensors.Due to the advantages of intrinsic signal amplification,bionic ability,and mechanical flexibility,electrochemical transistors(ECTs)have recently gained increasing popularity in constructing various sensors.In the current work,we have proposed a pulse-driven synaptic ECT for supersensitive and ultrafast biosensors.By pulsing the presynaptic input(drain bias,VD)and setting the modulation potential(gate bias)near transconductance intersection(VG,i),the synaptic ECT-based pH sensor can achieve a record high sensitivity up to 124 mV pH^(-1)(almost twice the Nernstian limit,59.2 mV pH^(-1))and an ultrafast response time as low as 8.75 ms(7169 times faster than the potentiostatic sensors,62.73 s).The proposed synaptic sensing strategy can effectively eliminate the transconductance fluctuation issue during the calibration process of the pH sensor and significantly reduce power consumption.Besides,the most sensitive working point at VG,i has been elaborately figured out through a series of detailed mathematical derivations,which is of great significance to provide higher sensitivity with quasi-nonfluctuating amplification capability.The proposed electrochemical synaptic transistor paired with an optimized operating gate offers a new paradigm for standardizing and commercializing high-performance biosensors.
基金supported by the National Natural Science Foundation of China(No.52173138)Natural Science Foundation of Hubei Province(No.2021CFB298)Natural Science Foundation of Shandong Province(No.ZR2021ME015).
文摘Formaldehyde(FA),as the simplest endogenous carbonyl molecule,participates in many biosynthesis and metabolism in living organisms,such as nucleotides and adenosine triphosphate(ATP).FA concentrations are sub-millimolar in the normal healthy body,but can rise significantly in a number of disease pathologies.As a result,detecting endogenous FA is critical for illness diagnosis and rehabilitation therapy monitoring.Recent studies have focused on the FA-responsive turn-on fluorescence probe,which has huge promise in the detection and visualization of FA in living cells and organisms,as well as exceptional use in disease diagnosis and therapeutic monitoring.This review summarizes the fluorescence luminescence mechanism and design concepts of FA fluorescent probes,as well as their recent applications in bioimaging and illness diagnostics.Additionally,this article indicates the present dilemma of FA-responsive fluorescent probe,including selectivity,specificity,and detection mode,which may provide references for the development of FA-responsive fluorescent probes.
文摘Over the past decade, biopolymers have gained great interests especially in biomedicine due to their physical properties and/or chemical structures changes in response to external stimuli in a certain time fiarne or at a specific location. Among them, poly(β-amino ester)s, methacrylate-based block copolymers and polypeptide with tertiary amine groups have been extensively studied and exhibit pH sensitive properties due to the protonation of tertiary amine groups. The pH values in normal organs, tissues, and subcellular compartments are always different from those in pathological tissues. These interesting properties allow their applications in a variety of fields ranging from diagnosis and therapeutics of diseases. Here, we review the recent progress of poly(β-amino ester)s, methacrylate-based block copolymers and polypeptide with tertiary amine groups and their applications in drug delivery and bioimaging.
基金financially supported by the National Natural Science Foundation of China(Nos.21704020,21374026,and51573032)the National Science Fund for Distinguished Young Scholars(No.51725302)financial support from the China Postdoctoral Science Foundation(No.2017M620707)
文摘The interfacing study of biopolymer and supramolecular chemistry enables a better understanding of fundamental biochemical processes and the creating of new high-performance biomaterials. In this review, we introduced an "in vivo self-assembly" strategy which means in situ construction of functional self-assembled superstructures in specific physiological or pathological conditions in cell, tissue or animal levels that exhibit diverse biomedical effects. By using this strategy, unexpected phenomena and insights, e.g, assembly/aggregation induced retention (AIR) effect have been demonstrated where the self-assembled nanostructures showed extraordinary enhanced accumulation and retention of therapeutics in targeted sites.
基金supported by the National Key R&D Program of China(2021YFB3801002)the National Natural Science Foundation of China(31870998,51725302 and 11621505)+1 种基金the Strategic Priority Research Program of the Chinese Academy of Sciences(XDB36000000)the Beijing Nova Program of Science and Technology(Z191100001119091 and Z211100002121148).
文摘The self-assembled nanomaterials based on peptides,which have not only good biocompatibility and low toxicity but also high stability and performance,are increasingly becoming an important way for cancer treatment.In this review,we highlight the progress of in vivo self-assembled polymer-peptide conjugates(PPCs)and their application,showing the recent advances in the development of“in vivo self-assembly”strategy for cancer treatment.Given the diverse microenvironments of tumor cells,different responsive assembly strategies(enzyme,pH,redox,temperature,etc.)have been developed to precisely control the assembly at different biological levels,realizing enhanced drug delivery and improved anticancer efficacy.
基金supported by the National Key R&D Program of China(no.2018YFE0205400)the National Natural Science Foundation of China(nos.51725302 and 31870998)+1 种基金the Strategic Priority Research Program of the Chinese Academy of Sciences(no.XDB36000000)the Beijing Nova Program of Science and Technology(no.Z191100001119091).
文摘Luminogens with aggregation-induced emission(AIEgens)have a wide range of biomedical applications in bioimaging,photodynamic anticancer,antibacterial therapy,and other fields,owing to their unique photophysical properties.The precise structural design and modification of AIE molecules have aroused great interest in the past years.As peptides-AIE hybrid materials,peptide-based AIEgens generally have better solubility,biocompatibility,and lower systemic toxicity.The functional diversity,modularity,and portability of peptides provide more possibilities for the intelligent structure and functional design of AIEgens.This review summarizes the recent research progress of peptide-based AIEgens nanomaterials,from molecular design,stimuli responsiveness to biomedical application,focusing on the advantages of peptides and AIE molecules as conjugates.Finally,a summary of the challenges and opportunities of peptide-based AIEgens nanomaterials for future clinical biomedical applications is presented.
